The community-acquired methicillin-resistant S. aureus (MRSA) USA300 SF8300 strain, a kind gift from Dr. Binh Diep (UCSF), was cultured in tryptic soy broth (TSB) as previously described (13, 14). Briefly, SF8300 was streaked onto a tryptic soy agar (TSA) plate (TSB plus 1.5% bacto agar (BD Biosciences)) and grown overnight at 37°C in a bacterial incubator. Two to three single colonies were picked and cultured in TSB at 37°C in a shaking incubator (240 rpm) overnight (18 h), followed by a 1:50 subculture at 37°C for 2 h to obtain mid-logarithmic phase bacteria. The bacteria were pelleted, washed 3 times with sterile PBS, resuspended in sterile freezing medium (10% glycerol in sterile PBS) at a concentration of 1×10¹⁰ CFU/ml and aliquots stored in cryovials at -80°C until needed. The number of CFUs was confirmed with overnight culture on TSA plates.

Age-matched 6-8-week-old female mice on C57BL/6 background were used for all experiments. The IL-1α^–/–, IL-1β^–/–, and IL-17A/F^–/– mice were provided by Dr. Yoichiro Iwakura (University of Tokyo). The VE-Cad^Cre×IL-1R^fl/fl (VE-Cad-IL-1R^–/–) mice, which lack IL-1R signaling in endothelial cells were provided by Dr. Michael O’Connell (NIH/NIAID). WT C57BL/6, TNF-α^–/– (B6.129S-tnf^tm1Gkl/J), IL-1R^–/– (B6.129S7-l1r1^tm1Imx/J), Lck^Cre (B6.Cg-Tg(Lck-cre)548Jxm/J), LysM^Cre (B6.129P2-Lyz2^tm1(cre)Ifo/J), CD4^Cre (Tg(Cd4-cre)1Cwi/BfluJ), S100A8^Cre (B6.Cg-Tg(S100A8-cre,-EGFP)1Ilw/J), TCRδ^CreER (B6.129S-Tcrd^{tm1.1(cre/ERT2)Zhu}/J), and IL-1R^fl/fl mice (B6.129(Cg)-Il1r1^tm1.1Rbl/J) were obtained from Jackson Laboratories (Bar Harbor, ME).

Lck^Cre mice were crossed with IL-1R^fl/fl mice to obtain Lck^Cre×IL-1R^fl/fl (Lck-IL-1R^–/–), which lack IL-1R signaling in pan-T cells. LysM^Cre were crossed with IL-1R^fl/fl mice to obtain LysM^Cre×IL-1R^fl/fl (LysM-IL-1R^–/–) mice, which lack IL-1R signaling in myeloid cells. S100A8^Cre were crossed with IL-1R^fl/fl mice to obtain S100A8^Cre×IL1R^fl/fl (S100A8-IL-1R^–/–) mice, which lack IL-1R signaling in neutrophils. CD4^Cre were crossed with IL-1R^fl/fl mice to obtain CD4^Cre×IL1R^fl/fl (CD4-IL-1R^–/–) mice, which lack IL-1R signaling in CD4-expressing cells, including both CD4⁺ and CD8⁺ T cells (due to dual expression of CD4 in both T cell types during thymic development). TCRδ^CreER mice were crossed with IL-1R^fl/fl mice to obtain TCRδ^CreER×IL1R^fl/fl (TCRδ-IL-1R^–/–) mice, which lack IL-1R signaling in γδ T cells upon tamoxifen-inducible deletion.

All mouse strains were bred and maintained under the same specific pathogen-free conditions, with air-isolated cages at an American Association for the Accreditation of Laboratory Animal Care (AAALAC)-accredited animal facility at Johns Hopkins University and handled according to procedures described in the Guide for the Care and Use of Laboratory Animals as well as Johns Hopkins University’s policies and procedures as outlined in the Johns Hopkins University Animal Care and Use Training Manual. This study was approved by the Johns Hopkins Animal Care and Use Committee (Protocol #: MO21M378).

The S. aureus bacteremia model was modified from previously described protocols (15, 16). Briefly, 6-to-8-week-old female C57BL/6 mice were anesthetized (inhalation of 2% isoflurane) and inoculated intravenously with 4.8-5.8 × 10⁷ SF8300 in a 100-μL volume of PBS using a 29-gauge insulin syringe via the retro-orbital vein to achieve an LD90.

The inducible deletion of IL-1R on γδ T cells was modified from a previously described protocol (17). The TCRδ-IL-1R^–/– mice were treated daily with 100 μl of 1 mg/ml tamoxifen in sunflower oil injected intraperitoneally for 5 consecutive days. The bacteremia infections were performed 10 days after the last tamoxifen injection. Wild-type (WT) mice were subjected to the same tamoxifen regimen when paired with TCRδ-IL-1R^–/– mice. Tamoxifen-inducible deletion of IL-1R was confirmed by flow cytometry, which was comparable to the ~60% deletion efficiency in γδ T cells in TCRδ^creER mice based on prior reports (18).

For flow cytometric analysis, 100 μl of peripheral blood and spleen was collected from tamoxifen-treated WT and TCRδ-IL-1R^–/– mice 3h after intravenous infection. Red blood cells were lysed with ACK lysis buffer (ThermoFisher Scientific) and cells were resuspended in FACS buffer (PBS containing 1% BSA and 2mM EDTA). Spleen was manually pushed through a cell separation filter (40 µm) and resuspended in FACS buffer. Single cell suspensions were stained for viability (Viobility 405/520 viability kit, Miltenyi Biotec) and TruStain fcX (Biolegend) was used to block Fc receptor binding. Next, blood single cells were surface stained with the following mAbs: PE-Vio770-CD3 (REA641, Miltenyi Biotec), PE-CD8a (REA601, Miltenyi Biote), APC-Vio770-CD4 (REA604, Miltenyi Biote) VioBlue-TCRγδ (REA633, Miltenyi Biotec), and APC-CD121α (clone JAMA-147, BioLegend). The γδ T cells were identified as CD3⁺CD4^-CD8^-TCRγδ⁺ cells from the live cell population. Spleen single cells were surface stained with the following mAbs: PerCP-Vio700-CD45 (REA737, Miltenyi Biotec), APC-CD11b (REA592, Miltenyi Biotec), VioBlue-Ly6C (REA796, Miltenyi Biotec), APC-Vio770-Ly6G (REA526, Miltenyi Biotec), and PE-Vio770-F4/80 (REA126, Miltenyi Biotec). Cell acquisition was performed on a MACSQuant analyzer (Miltenyi Biotec) and data analyzed using MACSQuantify software (Miltenyi Biotec). See Supplementary Figure 1 for gating strategy.

At 3h post infection, mice were euthanized, and the spleen, liver, and kidneys were harvested and ex vivo CFU were isolated as previously described (5, 19). The tissue specimens were homogenized (PRO200 Series homogenizer; PRO Scientific) and then serially diluted and cultured overnight on TSA plates at 37°C. Ex vivo CFU from the homogenized tissue were then enumerated from the plates.

Survival rates were compared by log rank (Mantel-Cox) test and data from single comparisons analyzed by Student’s t test (two-tailed), as indicated in the figure legends. All statistical analyses were calculated with Prism software (GraphPad 9.5 Software, La Jolla, California). CFU data are presented as geometric mean ± geometric standard deviation (SD). All other data are presented as mean ± standard error of the mean (SEM) and values of P <0.05 were considered statistically significant.

The levels of IL-1, IL-17, and TNF-α cytokines in circulation have been associated with predictive outcomes in patients with S. aureus bacteremia (4, 9–12). Therefore, we set out to determine the mechanistic effect of IL-1α/β, TNF-α, and IL-17A/F on survival during S. aureus bacteremia using a preclinical mouse model whereby 4.8-5.8 × 10⁷ CFUs of S. aureus USA300 (SF8300) were injected i.v. and survival measured over time (15, 16). To determine the role of IL-1R signaling, we first performed our bacteremia model on wild-type (WT) C57BL/6 and IL-1R^–/– mice and found that IL-1R^–/– mice had a statistically significant decrease in survival compared to WT mice ( Figure 1A ). Since IL-1α and IL-1β signal through the IL-1R (20), we next tested IL-1α^–/– and IL-1β^–/– mice and discovered that both IL-1α^–/– and IL-1β^–/– mice had a markedly reduced survival compared to WT mice ( Figure 1A ). Next, we examined IL-17A/F^–/– and TNF-α ^–/– mice and found no statistically significant differences compared to WT mice ( Figure 1B ). Taken together, our data indicated that IL-1α and IL-1β signaling via IL-1R enhanced survival during S. aureus bacteremia infections.

Since IL-1R signaling was important for survival during S. aureus bacteremia infections, we next elucidated the specific cell types involved in the IL-1R response. Various cell types use IL-1R signaling to drive host defense and inflammation (20), including myeloid cells, T cells, and non-immune cells (21). Thus, we developed mice with specific deletion of IL-1R in T cells (Lck-IL-1R^–/–), myeloid cells (LysM-IL-1R^–/–), and neutrophils (S100A8-IL-1R^–/–). We also used mice with specific deletion of IL-1R in endothelial cells (VE-Cad-IL-1R^–/–), since S. aureus interacts with endothelial cells upon bacteremia infections (22). We discovered that only the Lck-IL-1R^–/– mice had a significant defect in survival compared to WT mice ( Figure 2A ), suggesting that IL-1R signaling on T cells, but not myeloid cells, neutrophils, or endothelial cells was important for host survival.

We next determined the specific T cell subset required for IL-1R signaling, since CD4+ and γδ T cells are reported to be involved in host defense against S. aureus infections (7, 23–25). To this end, we developed and tested mice with specific deletion of IL-1R in CD4+ T cells (CD4-IL-1R^–/–) and tamoxifen-inducible deletion of IL-1R in γδ T cells (TCRδ-IL-1R^–/–). We discovered that CD4-IL-1R^–/– mice had no difference in survival compared to WT mice ( Figure 2B ). Interestingly, there was markedly decreased survival in TCRδ-IL-1R^–/– mice compared to WT mice ( Figure 2C ). There was a trend towards increased circulating γδ T cells counts in TCRδ-IL-1R^–/– mice compared to WT mice ( Figure 3A ). We confirmed tamoxifen-inducible deletion of IL-1R on γδ T cells in the TCRδ-IL-1R^–/– mice by flow cytometry ( Figure 3B ). Collectively, IL-1R signaling on γδ T cells was important for survival during S. aureus bacteremia infections.

We next elucidated whether γδ T cell-intrinsic IL-1R signaling affected immune cell levels and S. aureus burden during the bacteremia. To this end, we first measured neutrophil, monocyte, and macrophage population levels in the spleens of TCRδ-IL-1R^–/– and WT mice 3 hours post-infection. We found that monocytes, but not neutrophils or macrophages, were significantly decreased in TCRδ-IL-1R^–/– mice compared to WT mice ( Figures 3C-E ). Next, we measured S. aureus CFUs in the spleen, liver, and kidney, but found no difference in bacterial burden between TCRδ-IL-1R^–/– and WT mice ( Figures 3F-H ). These data indicated that γδ T cell-intrinsic IL-1R signaling promoted monocyte recruitment to the spleen during S. aureus bacteremia.